When the Archean began, the Earth's
heat flow was nearly three times as high as it is today, and it was still twice the current level at the transition from the Archean to the Proterozoic (2,500 ). The extra heat was partly remnant heat from
planetary accretion, from the formation of the
metallic core, and partly arose from the decay of
radioactive elements. As a result, the Earth's mantle was significantly hotter than today. flow over time Although a few mineral grains have survived from the
Hadean, the oldest rock formations exposed on the surface of the Earth are Archean. Archean rocks are found in
Greenland,
Siberia, the
Canadian Shield,
Montana,
Wyoming (exposed parts of the
Wyoming Craton),
Minnesota (Minnesota River Valley), the
Baltic Shield, the
Rhodope Massif,
Scotland,
India,
Brazil, western
Australia, and southern
Africa.
Granitic rocks predominate throughout the crystalline remnants of the surviving Archean crust. These include great melt sheets and voluminous
plutonic masses of
granite,
diorite,
layered intrusions,
anorthosites and
monzonites known as
sanukitoids. Archean rocks are often heavily metamorphosed deep-water sediments, such as
graywackes,
mudstones, volcanic sediments, and
banded iron formations.
Volcanic activity was considerably higher than today, with numerous lava eruptions, including unusual types such as
komatiite.
Carbonate rocks are rare, indicating that the oceans were more acidic, due to dissolved
carbon dioxide, than during the Proterozoic.
Greenstone belts are typical Archean formations, consisting of alternating units of metamorphosed
mafic igneous and sedimentary rocks, including
Archean felsic volcanic rocks. The metamorphosed igneous rocks were derived from volcanic
island arcs, while the metamorphosed sediments represent deep-sea sediments eroded from the neighboring island arcs and deposited in a
forearc basin. Greenstone belts, which include both types of metamorphosed rock, represent
sutures between the protocontinents.
Plate tectonics likely started vigorously in the
Hadean, but slowed down in the Archean. The slowing of plate tectonics was probably due to an increase in the viscosity of the
mantle due to outgassing of its water. Only at the end of the Archean did the continents likely emerge from the ocean. The emergence of continents towards the end of the Archaean initiated continental weathering that left its mark on the oxygen isotope record by enriching seawater with isotopically light oxygen. Due to recycling and metamorphism of the Archean crust, there is a lack of extensive geological evidence for specific continents. One hypothesis is that rocks that are now in India, western Australia, and southern Africa formed a continent called
Ur as of 3,100 Ma. Another hypothesis, which conflicts with the first, is that rocks from western Australia and southern Africa were assembled in a continent called
Vaalbara as far back as 3,600 Ma. Archean rock makes up only about 8% of Earth's present-day continental crust; the rest of the Archean continents have been recycled. There are well-preserved
sedimentary basins, and evidence of
volcanic arcs, intracontinental
rifts, continent-continent collisions and widespread globe-spanning
orogenic events suggesting the assembly and destruction of one and perhaps several
supercontinents. Evidence from banded iron formations,
chert beds, chemical sediments and
pillow basalts demonstrates that liquid water was prevalent and deep oceanic basins already existed. Asteroid impacts were frequent in the early Archean. Evidence from
spherule layers suggests that impacts continued into the later Archean, at an average rate of about one impactor with a diameter greater than every 15 million years. This is about the size of the
Chicxulub impactor. These impacts would have been an important oxygen sink and would have caused drastic fluctuations of atmospheric oxygen levels. ==Environment==